Hello everyone! Welcome to advanced neurobiology!
Neuroscience is a wonderful branch of science on how our brain perceives the external world, how our brain thinks, how our brain responds to the outside of the world, and how during disease or aging the neuronal connections deteriorate. We’re trying to understand the molecular, cellular nature and the circuitry arrangement of how nervous system works.
Through this course, you'll have a comprehensive understanding of basic neuroanatomy, electral signal transduction, movement and several diseases in the nervous system.
This advanced neurobiology course is composed of 2 parts (Advanced neurobiology I and Advanced neurobiology II, and the latter will be online later). They are related to each other on the content but separate on scoring and certification, so you can choose either or both. It’s recommended that you take them sequentially and it’s great if you’ve already acquired a basic understanding of biology.
Thank you for joining us!

Enseigné par

Yan Zhang

Professor

Yulong Li

Research Fellow

Transcription

So L-dopa can be metabolized inside our body into dopamine. It is the most effective drug to treat this disease nowaday. So the principle is very simple. If the neuron that are responsible for making dopamine die, then you simply put back dopamine. That will improve the symptom. The disadvantage or the side effect of this drug is only small portion of this drug can cross the blood-brain barrier. And then the remaining part, the major part of this drug remains in the other sites of the body. So there are lots of side effects induced by this drug including nauseous and stiffness. And the other major disadvantage of this drug is because loss of dopaminergic neuron in the substantia nigra died already and then you try to put in L-dopa to rescue the phenotype. And then the still alive dopaminergic neuron in that brain region will sense this exogenous L-dopa and then it will tell the brain now we have enough dopa. So the still alive dopaminergic neurons now stop making dopamine. So it’s just like a feedback loop and it will make disease worse. So in the patients taking this drug we often see on stage and off state. The on state is when you take the drug and then the drug is effective we call it on state. The off state is no matter how much you take the drug we don't see effective effect of this drug, so you can have on and off state. And we have other similar drugs. One is dopamine agonists. It's not dopamine, it's not dopamine itself. It can act on the dopamine receptors and then can agonists improve the of dopamine receptors. And the dopamine is synthesized, is metabolized, is degraded by the MAO-B enzyme. So if you use the MAO-B inhibitors to decrease the degradation of dopamine, then we can kind of improve the symptom as well. And also there are suggestions for genes therapy, but this has not been used in clinic yet, it's just in the trial. And also people suggest some trophic factors, some growth factors can be protective or can be beneficial for this disease. For example, the GDNF can improve the symptom in the disease. And also there are suggestions for transplant, neuronal transplantations. We transplant some healthy dopaminergic cells, neurons, to that brain region or we induce neurons from the stem cell, neuronal stem cell in that brain region. These are also trials as well. These therapies are not widely used in clinic yet. And then the other thing used in practice is deep brain stimulation. As we said, L-dopa can have lots of side effect, and the patient normally have on state and off state. So during off state, when patients are not responsive to L-dopa at all, then the clinicians can use this deep brain stimulation instead. So the principle of this deep brain stimulation is put in a electrode into the substantia nigra region and then give a electrical shock in that brain region. So this is the picture, this is the skull, this is the head of the patient. You put in a electrode down to that midbrain region, and then with the stimulator you can give electric shock directly in that brain region. And in that brain region, we have lots of dopaminergic neurons, so by that electrical shock we stimulate a group of neurons together, and then during that shock, dopaminergic neuron can release a huge amount of dopamine within that shock area. That could be effective for, one deep brain stimulation can last for about one month. So after one month the patient needs to go back again and then receive another shock. And because in the deep brain stimulation, we use electric shock, we use an electrical stimulation. So in that brain area, in that substantia nigra brain area, we don't only have dopaminergic neurons. We also have lots of excitatory neuron and other neurons like gabanergic neurons or serotonin neurons. So if you use electrical shock, you stimulate all the neurons in one brain region. So we have side effect of overactivate excitatory neurons. To overcome that, so now we have another tool we called optogenetics. The protocol we use now is developed by Dr. Karl Deisseroth in 2005. So the principle of this technique is used to channels or region from a and these channels can responsible to different wavelengths of light. For example, this channel here, called ChR2, this channel can respond to the blue light. And then when blue light shine on this channel, this channel can open and then the sodium ion can go in, the potassium ion can go out. This is not an ion channel, this is a transporter. And then when this transporter was shined with this yellow light here, and then this transporter will be activated and it will transport chlorine ion from outside of the cell to inside of the cell. So the effect of this two channel activation are totally opposite. When this ChR2 channel is activated, it can depolarize the cell. And when this NpHR is activated, it can hyperpolarize the cell, right? So Karl, very smartly, put these channels onto the surface of neuron. And to activate this ChR2, it's just equal to activate the neuron, depolarize the neuron and then make the neuron activate. And in this channel, NpHR, is to used to hyperpolarize the cell, to make the neuron inactive. So basically with these two channels or transporters, people can control the activation of certain group of neurons by the blue light or yellow light. And the advantage of this system is these two proteins can be genetically coded. So by manipulated the promoter of these genetic expression vectors, we can specifically express these proteins in certain group of neurons. For example, if I just want to activate dopaminergic neurons, then I can use this ChR2. So for example, if I want to activate only dopaminergic neurons in certain brain area, so I can put in this ChR2 protein expression vector only under the dopaminergic promoter, the specific promoter. So the ChR2, only this protein, will only be expressed in dopaminergic neurons. When I shined light in these certain brain areas, then all the neurons will receive the light, but only the dopaminergic neuron surface would express this channel, this ChR2. So only the dopaminergic neuron will be activated upon the light. So this is the actual picture happen in a mouse brain using optogenetics. So this is the optic fiber that would deliver light here. And then this is a schematic drawing of a brain area that transfected with ChR2. So the red neuron indicate the neurons with ChR2 and then the black neuron are the neurons without this ChR2 protein. So when light is delivered here, only the red neurons, only the neurons with ChR2, can be activated by this light, and the black neurons are not affected. This is the picture in Karl Deisseroth's paper. That one there's top panel is the action potential recorded with the electrical stimulation. And then the bottom panel the blue dot there shows the point they turn on the blue light. And then you can see from the each blue light stimulation we can have the activation of neurons, just as you stimulate with electric signals. So compared to the traditional electrical stimulation, optical stimulation because you can genetically code the expression of your ion channels, so you can have specific effect in the target neuronal group not in whole area. And then compare to the drug, you can see in this brain region if I just want to activate dopaminergic neuron, I can use dopamine receptor agonist to mimic this effect. But the advantage of optical genetics compared to drug treatment is it's reversible very quickly. For the drug, if you put in certain brain area and you want to wash it out, at least it will take half an hour to wash out the effect. But for this protocol you just need to turn off the light. Then you can shut down the effect. So these are two papers by Karl Deisseroth's group using this technique to study the mechanism of Parkinson's disease. And then this optical genetic system are not the only system. There are some other system as well. One system developed by Gero Miesenbock in 2005 in a fruit fly is to deplete the neuronal ATP first and then in the motor neuron in one side of the body of fruit fly. And then he put in caged ATP into these motor neurons. And then he will break the cage with certain wavelengths of light, and then with the breakage of the caged ATP get released so these motor neuron get activated. And because he only transferred these caged ATP into one side of the motor neuron in fruit fly body, so he can control the movement direction by this technique. In that paper he gave it a fancy name called remote control of the fruit fly. And then there's another system, developed by Kramer, Isacoff, and Trauner in 2004. They use a potassium channel and then before activation, this potassium channel is blocked by a chemical and this chemical has a linker with the channel. And then with the UV light, the conformation of the linker changed and then to pull ofl this blocking molecule and in this channel become open. So this is another system.